CN117815557A - Defibrillation monitoring equipment, monitoring assembly and defibrillation monitoring assembly - Google Patents

Abstract

A defibrillation monitoring device, a monitoring component and a defibrillation monitoring component, wherein the defibrillation monitoring device comprises a host computer and a monitoring device. The host and the monitoring device can be combined and split in a detachable connection mode. The host machine can independently finish defibrillation operation at the same time, and can only carry the host machine to go to a medical rescue place when the host machine needs to go out to perform defibrillation operation independently. The monitoring device can independently realize the monitoring function, and can only carry the monitoring device to go to a medical rescue place when the patient needs to go out to independently carry out the monitoring operation. Therefore, the user can flexibly select the carried equipment according to the needs, and the convenience of use is improved. Meanwhile, the monitoring device is further provided with a first storage part which can be used for storing monitoring accessories (such as a sensor, a connecting wire and the like), so that the monitoring accessories are prevented from being placed in disorder to occupy the space which is already limited, and the work of a user is prevented from being influenced.

Description

Defibrillation monitoring equipment, monitoring assembly and defibrillation monitoring assembly

Technical Field

The present application relates to the field of medical devices, and in particular to the structure of defibrillation monitoring devices.

Background

Defibrillation operations and vital sign monitoring are very important operations in medical settings, such as pre-hospital emergency settings where specialized emergency personnel need to carry a lot of emergency equipment to the scene, including vital sign monitoring equipment (simply referred to as monitoring equipment) and defibrillation equipment.

In some products, the monitoring device and the defibrillation device are independent devices, and occupy the space area of the medical place very much. Moreover, when medical staff needs to go out for medical assistance, the medical staff often needs to carry two devices, namely a monitoring device and a defibrillation device, which causes great inconvenience to the medical staff.

In other products, a modularized design is performed, and the display module, the monitoring module and the defibrillation module are arranged as three combinable modules which can be combined into a whole structure. However, since both the monitoring module and the defibrillation module need to be used together with the display module, there is still a problem that the monitoring or defibrillation operation is inconvenient to carry when the monitoring or defibrillation operation is required separately.

Disclosure of Invention

The application provides a defibrillation monitoring device so as to improve the use convenience of the defibrillation monitoring device.

The application provides a guardianship subassembly to realize guardianship module and other devices's detachable combination, make things convenient for guardianship module's carrying simultaneously.

The application provides a monitoring assembly so as to be convenient for accommodating monitoring accessories and reduce occupation of the monitoring accessories to space.

The application provides a defibrillation guardianship subassembly to realize the detachable combination of defibrillation guardianship all-in-one and other devices, make things convenient for the carrying of defibrillation guardianship all-in-one simultaneously.

The present application provides a defibrillation monitoring assembly to facilitate receiving defibrillation and/or monitoring accessories, reducing occupation of space by the defibrillation and/or monitoring accessories.

In view of the foregoing, one embodiment of the present application provides a defibrillation monitoring device, including:

the host comprises a host shell, a host control unit, a host display unit, a high-voltage capacitor, a charging circuit, a discharging circuit and a host information transmission unit for information transmission, wherein the host display unit is at least used for displaying defibrillation information;

the host control unit receives and controls the charging circuit and the discharging circuit to complete the charging and discharging process of the high-voltage capacitor and generates corresponding defibrillation information;

the host shell is provided with a first accommodating cavity, the host control unit, the high-voltage capacitor, the charging circuit and the discharging circuit are all positioned in the first accommodating cavity, and the host display unit is arranged on the front side of the host shell;

The monitoring device can be detachably arranged on the assembly structure; the monitoring device can realize the monitoring function when being arranged and not arranged in the assembly structure, and the host is in communication connection with the monitoring device through the host information transmission unit so as to realize unidirectional or bidirectional information transmission; and

the first storage piece is used for storing the monitoring accessory and is detachably connected with the monitoring device, and is not detachably fixedly connected with the monitoring device or integrally formed with the monitoring device.

In one embodiment, at least two faces of the host housing define an expansion module mounting area; when the monitoring device is mounted to the mounting structure, the monitoring device is at least partially received in the expansion module mounting area.

In one embodiment, the monitoring device is positioned on at least one of the left side, the right side, the rear side, the upper side and the lower side of the host display unit when the monitoring device is mounted to the mounting structure.

In one embodiment, the monitoring device is located at the rear side of the host display unit when the monitoring device is mounted to the mounting structure.

In one embodiment, the monitoring device is capable of entering and/or exiting from at least one of a rear side, a left side, a right side, an upper side, and a lower side of the expansion module mounting area.

In one embodiment, at least one of the rear, left, right, upper and lower sides of the expansion module mounting area is open, and the monitoring device is accessible from at least one open side exposed or provided with an openable and closable covering structure into and/or out of the expansion module mounting area.

In one embodiment, the main housing has a support table including a support surface, at least two surfaces of the main housing defining the expansion module mounting area including the support surface; the expansion module installation area is positioned on the upper side of the supporting table, and the supporting surface is used for supporting the monitoring device.

In one embodiment, the support stand is located at a rear side of the host display unit, and the monitoring device is capable of being placed on and/or removed from the support stand from at least one of a rear side, a left side, a right side, and an upper side of the expansion module mounting area.

In one embodiment, when the defibrillation monitoring device is placed horizontally, the host display unit forms a first angle with the vertical direction, and the supporting surface is inclined downward at the first angle along the front-to-back direction in cooperation with the first angle.

In one embodiment, at least two faces of the host housing defining the extension module mounting area include sides located on a front side of the extension module mounting area, and the host information transfer unit includes a docking portion for connecting the monitoring device, the docking portion being located on the sides located on the front side of the extension module mounting area.

In one embodiment, the host includes a chest resistance detection circuit, the chest resistance detection circuit is configured to obtain chest resistance detection data, and the host control unit receives the chest resistance detection data and controls the charging circuit and the discharging circuit to complete the charging and discharging process of the high-voltage capacitor.

In one embodiment, the monitoring device comprises a monitoring module, wherein the monitoring module is provided with a monitoring module control unit for receiving and processing monitoring data, a monitoring module display unit for displaying the monitoring data and a monitoring module information transmission unit, and the monitoring module information transmission unit can be in communication connection with the host information transmission unit so as to realize unidirectional or bidirectional information transmission.

In one embodiment, the monitoring module has a first docking structure for detachable connection with the mounting structure.

In one embodiment, the monitoring device further comprises a second receiving member having a receiving cavity for receiving the monitoring module and a second docking structure for detachable connection with the mounting structure.

In one embodiment, when the monitoring module is stored in the storage cavity, the monitoring module display unit is not blocked by the second storage piece; the second storage piece is provided with an information transfer unit, the information transfer unit is provided with a monitoring module docking part and a host docking part, the monitoring module docking part is used for being in communication connection with a monitoring module information transmission unit of the monitoring module, and the host docking part is used for being in communication connection with a host information transmission unit of the host.

In one embodiment, the second storage member includes a plurality of separate sub storage members, and the plurality of sub storage members are integrally formed, non-detachably connected fixedly or detachably connected.

In one embodiment, the first receiving member is detachably connected to the monitoring module.

In one embodiment, the first receiving member and the second receiving member are detachably connected, non-detachably fixedly connected or integrally formed.

In one embodiment, the first receiving member is located on at least one of a rear side, a left side, and a right side of the monitoring device.

In one embodiment, the first receiving member is disposed on the left and right sides of the monitoring module or the second receiving member, respectively.

In one embodiment, the first storage member includes a plurality of separate sub-storage members, and the plurality of sub-storage members are integrally formed, non-detachably connected fixedly or detachably connected.

In one embodiment, the projection of the first storage member and the projection of the main body at least partially overlap on a cross section of the defibrillation monitoring device perpendicular to the bottom surface along the front-rear direction.

In one embodiment, on a cross section of the defibrillation-monitoring apparatus perpendicular to the bottom surface along the left-right direction, the projection of the first storage member does not overlap with the projection of the main unit, or overlaps with the projection portion of the main unit.

In one embodiment, the device further comprises a third accommodating part, wherein the third accommodating part is used for accommodating the electrode slice and/or the electrode slice cable;

the third storage piece is detachably connected with the monitoring device or the host machine, and is fixedly connected or integrally formed.

In one embodiment, the third receiving member is provided on the side surface located on the front side of the expansion module mounting region and/or the rear side of the support stand.

In one embodiment, the third receiving member is disposed parallel to the host display unit.

In view of the foregoing, one embodiment of the present application provides a defibrillation monitoring device, including:

a display device including a display device housing, a display device display unit, and a display device information transmission unit for information transmission, the display device housing having an assembly structure;

and a defibrillation monitoring device detachably mountable to the mounting structure; and

the first storage piece is used for storing the accessories for defibrillation and/or monitoring and is detachably connected, non-detachably fixedly connected or integrally formed with the defibrillation monitoring device;

the defibrillation monitoring device comprises a defibrillation monitoring integrated machine, wherein the defibrillation monitoring integrated machine comprises an integrated machine shell, an integrated machine display unit for displaying information, a high-voltage capacitor, a chest resistance detection circuit, a charging circuit, a discharging circuit, an integrated machine information transmission unit for information transmission, a monitoring parameter circuit and an integrated machine control unit;

The integrated machine information transmission unit can be in communication connection with the display device information transmission unit so as to realize unidirectional or bidirectional information transmission;

the monitoring parameter circuit is used for receiving vital sign data of a detected object and transmitting the vital sign data to the integrated machine control unit, and the integrated machine control unit generates corresponding monitoring information;

the integrated machine control unit controls the charging circuit and the discharging circuit to complete the charging and discharging process of the high-voltage capacitor and generate corresponding defibrillation information;

the integrated machine control unit is also used for controlling the integrated machine display unit to display the defibrillation information and the monitoring information;

the integrated machine shell is provided with a second accommodating cavity, the high-voltage capacitor, the charging circuit, the discharging circuit, the integrated machine information transmission unit, the integrated machine control unit and the monitoring parameter circuit are all positioned in the second accommodating cavity, and the integrated machine display unit is arranged in the integrated machine shell;

the defibrillation monitoring device can realize defibrillation function and monitoring function when being arranged and not arranged on the assembly structure; the display device is in communication connection with the defibrillation monitoring device through the display device information transmission unit so as to realize unidirectional or bidirectional information transmission;

The display unit of the display device is arranged on the front side of the display device shell and is used for displaying the defibrillation information and the monitoring information transmitted by the defibrillation monitoring device.

In one embodiment, at least two faces of the display device housing define an expansion module mounting area; the defibrillation-monitoring device is at least partially received within the extension module mounting area when the defibrillation-monitoring device is mounted to the mounting structure.

In one embodiment, the defibrillation-monitoring device is located on at least one of the left, right, rear, upper and lower sides of the display unit of the display device when the defibrillation-monitoring device is mounted to the mounting structure.

In one embodiment, the defibrillation-monitoring device is capable of entering and/or exiting from at least one of a rear side, a left side, a right side, an upper side, and a lower side of the extension module mounting area.

In one embodiment, at least one of the rear, left, right, upper and lower sides of the extension module mounting area is open, and the defibrillation-monitoring device is capable of being accessed and/or removed from the extension module mounting area from at least one open side that is exposed or provided with an openable and closable covering structure.

In one embodiment, the display device housing has a support stand comprising a support surface, at least two faces of the display device housing defining the expansion module mounting area comprising the support surface; the extension module mounting area is positioned on the upper side of the supporting table, and the supporting surface is used for supporting the defibrillation monitoring device.

In an embodiment, the support stand is located at a rear side of the display unit of the display device, and the defibrillation-monitoring device is capable of being placed on and/or removed from the support stand from at least one of the rear side, the left side, the right side, and the upper side of the extension module mounting area.

In one embodiment, when the defibrillation monitoring apparatus is placed horizontally, the display unit of the display device forms a first angle with the vertical direction, and the supporting surface is inclined downward at the first angle along the direction from front to back in cooperation with the first angle;

at least two faces of the display device housing defining the extension module mounting area include sides located on a front side of the extension module mounting area, and the display device information transmission unit includes a docking portion for connecting the defibrillation-monitoring device, the docking portion being located on the sides located on the front side of the extension module mounting area.

In one embodiment, the defibrillation-monitoring unit has a first docking structure for detachable connection with the mounting structure.

In one embodiment, the defibrillation monitoring device further includes a second housing member having a housing cavity for housing the defibrillation monitoring integrated machine and a second docking structure for detachably connecting with the mounting structure.

In one embodiment, when the defibrillation-monitoring integrated machine is stored in the storage cavity, the integrated machine display unit is not blocked by the second storage piece; the second storage piece is provided with an information switching unit, the information switching unit is provided with an integrated machine butt joint part and a display device butt joint part, the integrated machine butt joint part is used for being in communication connection with an integrated machine information transmission unit of the defibrillation monitoring integrated machine, and the display device butt joint part is used for being in communication connection with the display device information transmission unit.

In one embodiment, the second storage member includes a plurality of separate sub storage members, and the plurality of sub storage members are integrally formed, non-detachably connected fixedly or detachably connected.

In one embodiment, the first storage member is fixedly connected with the defibrillation monitoring integrated machine.

In one embodiment, the first storage member is fixedly connected with the second storage member.

In one embodiment, the first housing is located on at least one of a rear side, a left side, and a right side of the defibrillation-monitoring device or the second housing.

In one embodiment, the first receiving member is disposed on the left and right sides of the defibrillation monitoring device or the second receiving member, respectively.

In one embodiment, the first receiving member includes a plurality of separate sub receiving members, and the plurality of sub receiving members are fixedly connected or detachably connected with each other.

In one embodiment, the projection of the first receiving member and the projection of the display device at least partially overlap each other in a cross section of the defibrillation monitoring apparatus perpendicular to the bottom surface in the front-rear direction.

In one embodiment, the projection of the first receiving member does not overlap with the projection of the display device or overlaps with the projection portion of the display device in a cross section of the defibrillation monitoring apparatus perpendicular to the bottom surface in the left-right direction.

In one embodiment, the device further comprises a third accommodating part, wherein the third accommodating part is used for accommodating the electrode slice and/or the electrode slice cable;

the third storage piece is detachably connected with the defibrillation monitoring device or the display device, and is not detachably fixedly connected or integrally formed.

In one embodiment, at least two faces of the display device housing defining the expansion module mounting region include side faces located on a front side of the expansion module mounting region, and the third receiving member is provided on the side faces and/or on a rear side of the support stand.

In one embodiment, the third receiving member is disposed parallel to the display unit of the display device.

In one embodiment, the display device includes a display device control unit that is capable of at least sending a defibrillation control signal to the all-in-one control unit to control the defibrillation monitoring device to defibrillate.

In view of the foregoing, one embodiment of the present application provides a monitoring assembly comprising:

the monitoring module is provided with a monitoring module control unit for receiving and processing monitoring data, a monitoring module display unit for displaying the monitoring data and a monitoring module information transmission unit;

and the second storage part is provided with a storage cavity for storing the monitoring module and a second butt joint structure, and the second butt joint structure comprises a detachable bonding structure, a magnetic attraction fixing structure, a clamping structure and/or a screw joint fixing structure.

In one embodiment, when the monitoring module is stored in the storage cavity, the monitoring module display unit is not blocked by the second storage piece; the second storage piece is provided with an information switching unit, the information switching unit is provided with a monitoring module butting part and a host butting part, the monitoring module butting part is used for being in communication connection with the monitoring module information transmission unit, and the host butting part is used for being in communication connection with the host.

In one embodiment, the second storage member includes a plurality of separate sub storage members, and the plurality of sub storage members are integrally formed, non-detachably connected fixedly or detachably connected.

In one embodiment, the monitoring accessory further comprises a first storage piece, wherein the first storage piece is fixedly connected with the second storage piece.

In one embodiment, the first receiving member is located on at least one of a rear side, a left side and a right side of the second receiving member.

In one embodiment, the first receiving member is disposed on both sides of the second receiving member.

In one embodiment, the first receiving member includes a plurality of separate sub receiving members, and the plurality of sub receiving members are fixedly connected or detachably connected with each other.

In an embodiment, the front side of the first storage member protrudes out of the second storage member, so that the second storage member and the first storage member form a concave structure, and the concave structure is used for being embedded and arranged on the host.

In view of the foregoing, one embodiment of the present application provides a monitoring assembly comprising:

the monitoring module is provided with a monitoring module control unit for receiving and processing monitoring data, a monitoring module display unit for displaying the monitoring data and a monitoring module information transmission unit; the monitoring module is provided with a first butt joint structure, and the first butt joint structure comprises a detachable bonding structure, a clamping structure and/or a screw joint fixing structure;

and the first storage piece is used for storing the monitoring accessory and is detachably connected with the monitoring module, and is non-detachably fixedly connected with the monitoring module or integrally formed with the monitoring module.

In one embodiment, at least one of the first receiving members is disposed on the left and right sides of the monitoring module.

In an embodiment, the front side of the first storage member protrudes out of the monitoring module, so that the first storage member and the monitoring module form a concave structure, and the concave structure is used for being embedded with the host.

In one embodiment, the first storage member includes a plurality of separated sub storage members, and the plurality of sub storage members are detachably connected, non-detachably fixedly connected or integrally formed.

In view of the foregoing, an embodiment of the present application provides a defibrillation monitoring assembly including a defibrillation monitoring unit and a second housing;

the defibrillation monitoring integrated machine comprises an integrated machine shell, an integrated machine display unit for displaying information, a high-voltage capacitor, a chest resistance detection circuit, a charging circuit, a discharging circuit, an integrated machine information transmission unit, an integrated machine control unit and a monitoring parameter circuit;

the integrated machine control unit controls the charging circuit and the discharging circuit to complete the charging and discharging process of the high-voltage capacitor;

the integrated machine information transmission unit can be connected with the display device to realize unidirectional or bidirectional information transmission;

the monitoring parameter circuit is used for receiving vital sign information of a detected object and transmitting the vital sign information to the control unit of the all-in-one machine;

the integrated machine control unit is also used for receiving and processing the vital sign information and the defibrillation instruction and controlling the integrated machine display unit to display corresponding defibrillation information and monitoring information;

The integrated machine shell is provided with a second accommodating cavity, and the high-voltage capacitor, the charging circuit, the discharging circuit, the integrated machine information transmission unit, the integrated machine control unit and the monitoring parameter circuit are all positioned in the second accommodating cavity;

the second storage piece is provided with a storage cavity for storing the defibrillation monitoring integrated machine; the second storage piece is provided with a second butt joint structure used for being detachably connected with the display device, and the second butt joint structure comprises a detachable bonding structure, a clamping structure and/or a screw fixing structure.

In one embodiment, when the defibrillation-monitoring integrated machine is stored in the storage cavity, the integrated machine display unit is not blocked by the second storage piece; the second storage piece is provided with an information switching unit, the information switching unit is provided with an integrated machine butt joint part and a display device butt joint part, the integrated machine butt joint part is used for being in communication connection with the integrated machine information transmission unit, and the display device butt joint part is used for being in communication connection with the display device.

In one embodiment, the second storage member includes a plurality of separated sub storage members, and the plurality of sub storage members are detachably connected, non-detachably fixedly connected or integrally formed.

In one embodiment, the device further comprises a first storage member for storing the defibrillation and/or monitoring accessories, wherein the first storage member is fixedly connected with the second storage member.

In one embodiment, the first receiving member is located on at least one of a rear side, a left side and a right side of the second receiving member.

In one embodiment, the first receiving member is disposed on both sides of the second receiving member.

In one embodiment, the first storage member includes a plurality of separated sub storage members, and the plurality of sub storage members are detachably connected, non-detachably fixedly connected or integrally formed.

In an embodiment, the front side of the first storage member protrudes out of the second storage member, so that the second storage member and the first storage member form a concave structure, and the concave structure is used for being embedded and arranged on the host.

In view of the foregoing, an embodiment of the present application provides a defibrillation monitoring assembly including a defibrillation monitoring unit and a first housing member;

the defibrillation monitoring integrated machine comprises an integrated machine shell, an integrated machine display unit for displaying information, a high-voltage capacitor, a chest resistance detection circuit, a charging circuit, a discharging circuit, an integrated machine information transmission unit, an integrated machine control unit and a monitoring parameter circuit;

The integrated machine control unit controls the charging circuit and the discharging circuit to complete the charging and discharging process of the high-voltage capacitor;

the integrated machine information transmission unit can be in communication connection with the display device so as to realize unidirectional or bidirectional information transmission;

the monitoring parameter circuit is used for receiving vital sign information of a detected object and transmitting the vital sign information to the control unit of the all-in-one machine;

the integrated machine control unit is also used for receiving and processing the vital sign information and the defibrillation instruction and controlling the integrated machine display unit to display corresponding defibrillation information and monitoring information;

the integrated machine shell is provided with a second accommodating cavity, and the high-voltage capacitor, the charging circuit, the discharging circuit, the integrated machine information transmission unit, the integrated machine control unit and the monitoring parameter circuit are all positioned in the second accommodating cavity;

the defibrillation monitoring integrated machine is provided with a first butt joint structure, wherein the first butt joint structure comprises a detachable bonding structure, a clamping structure and/or a screw fixing structure;

the first storage piece is used for storing accessories for defibrillation and/or monitoring and is detachably connected, non-detachably fixedly connected or integrally formed with the defibrillation monitoring integrated machine.

In one embodiment, at least one first storage member is respectively disposed on the left and right sides of the defibrillation-monitoring integrated machine.

In an embodiment, the front side of the first storage member protrudes out of the second storage member, so that the second storage member and the first storage member form a concave structure, and the concave structure is used for being embedded and arranged on the host.

In one embodiment, the first storage member includes a plurality of separated sub storage members, and the plurality of sub storage members are detachably connected, non-detachably fixedly connected or integrally formed.

The defibrillation monitoring device according to the above embodiment comprises a host computer and a monitoring apparatus. The host and the monitoring device can be combined and split in a detachable connection mode, and when the host and the monitoring device are required to be subjected to defibrillation and monitoring operation when going out, the host and the monitoring device can be combined into a whole, so that the portable device is convenient to carry. The host machine can independently finish defibrillation operation at the same time and can be at least used for displaying defibrillation information, so that the host machine can be carried only to go to a medical rescue place when the host machine needs to go out to perform defibrillation operation independently. The monitoring device can independently realize the monitoring function, and can only carry the monitoring device to go to a medical rescue place when the patient needs to go out to independently carry out the monitoring operation. Therefore, the user can flexibly select the carried equipment according to the needs, and the convenience of use is improved. Meanwhile, the monitoring device is further provided with a first storage part which can be used for storing monitoring accessories (such as a sensor, a connecting wire and the like), so that the monitoring accessories are prevented from being placed in disorder to occupy the space which is already limited, and the work of a user is prevented from being influenced.

The defibrillation monitoring device according to the above embodiment comprises a display device and a defibrillation monitoring device. The display device and the defibrillation monitoring device can be combined and split in a detachable connection mode, and the defibrillation monitoring device comprises a defibrillation monitoring integrated machine which can independently complete monitoring operation and defibrillation operation. When a larger display window is needed for display, the display device and the defibrillation monitoring device can be combined into a whole for use, and defibrillation information and monitoring information are displayed through the display device. However, when the weight and volume of the equipment are required to be reduced, the defibrillation monitoring device can be carried only to the medical rescue place. Therefore, the user can flexibly select the carried equipment according to the needs, and the convenience of use is improved. Meanwhile, the defibrillation monitoring device is also provided with a first storage part which can be used for storing defibrillation and/or monitoring accessories (such as a sensor for monitoring and a connecting cable, electrode plates for defibrillation, electrode plates and the like), so that the accessories are prevented from being placed in disorder to occupy the space which is already limited and the work of a user is prevented from being influenced.

The monitoring assembly according to the above embodiment comprises a monitoring module and a second receiving member having a housing for receiving the monitoring module, i.e. the monitoring module is placeable in the second receiving member. The second receiving member also has a second docking structure by which the second receiving member can be mounted to other devices, such as the host described above, along with the monitoring module, thereby enabling the monitoring module to form a detachable combination with the other devices.

The monitoring assembly according to the above embodiment includes a monitoring module and a first receiving member detachably connected, non-detachably fixed connected or integrally formed with the monitoring module. The first storage part can be used for storing the monitoring accessories (such as the sensor, the connecting cable and the like), so that the monitoring accessories are prevented from being placed in disorder to occupy the space which is already limited, and the work of a user is prevented from being influenced.

The defibrillation monitoring assembly according to the embodiment comprises a defibrillation monitoring integrated machine and a second accommodating part, wherein the second accommodating part is used for accommodating the defibrillation monitoring integrated machine, namely, the defibrillation monitoring integrated machine can be placed in the second accommodating part. The second receiving member is also provided with a second docking structure, and the second receiving member can be mounted on other devices together with the defibrillation monitoring integrated machine through the second docking structure, for example, the display device, so that the defibrillation monitoring integrated machine can form a detachable combined structure with other devices.

According to the embodiment, the defibrillation monitoring assembly comprises a defibrillation monitoring integrated machine and a first storage piece, wherein the first storage piece is detachably connected with the defibrillation monitoring integrated machine, is non-detachably fixedly connected with the defibrillation monitoring integrated machine or is integrally formed. The first storage part can be used for storing defibrillation and/or monitoring accessories (such as sensors and connecting cables for monitoring, electrode plates for defibrillation, electrode plates and the like), so that the accessories are prevented from being placed in disorder to occupy the limited space and the work of a user is prevented from being influenced.

Drawings

FIG. 1 is a schematic diagram showing a detachable combination of a host and a monitoring device according to an embodiment of the present application;

FIG. 2 is a schematic side view of a detachable combination of a host and a monitoring device according to an embodiment of the present application;

FIGS. 3 and 4 are schematic diagrams of an expansion module mounting area formed by three surfaces of a host housing in one embodiment of the present application;

FIG. 5 is a schematic diagram illustrating a configuration of an installation area of an expansion module on a host according to an embodiment of the present application;

FIG. 6 is a schematic diagram illustrating a process of assembling and disassembling the monitoring module from the second receiving member according to an embodiment of the present disclosure, wherein the monitoring device is provided with the first receiving member;

FIG. 7 is a schematic diagram illustrating a layout of cables on the monitoring module when the monitoring module is disposed on the second receiving member according to an embodiment of the present disclosure;

FIG. 8 is a schematic structural view of a monitoring device and a first receiving member according to another embodiment of the present disclosure;

fig. 9 and 10 are schematic structural views of a monitoring device and a first receiving member according to another more specific embodiment of the present application;

FIG. 11 is a schematic view of a third receiving member disposed at a rear side of the monitoring device according to an embodiment of the present disclosure;

FIGS. 12 and 13 are schematic views of a third housing member disposed on the rear side of the monitoring device and mounted to the host along with the monitoring device in one embodiment of the present application;

FIG. 14 is a schematic view of a third receiving member at a rear side of a host according to an embodiment of the present disclosure;

FIG. 15 is a schematic view of a third receiver positioned on a front side of an expansion module mounting area in one embodiment of the present application;

FIG. 16 is a schematic view of a third receiving member at a rear side of a host according to another embodiment of the present disclosure;

FIG. 17 is a schematic view of the monitor device and the first receiving member of the structure shown in FIG. 16;

FIG. 18 is a schematic view of a front bottom of a mainframe with an electrode pad mounting cavity in accordance with one embodiment of the present application;

FIG. 19 is a schematic view illustrating the storage of electrode pads and cables when the bottom of the front side of the mainframe is provided with an electrode pad mounting cavity and the left and right sides of the mainframe are provided with third storage members in an embodiment of the present application;

fig. 20 is a schematic view of an embodiment of the present application, in which the side surface on the front side of the mounting area of the expansion module has an electrode pad mounting cavity, and the rear side of the host has a third receiving member.

Detailed Description

The invention will be described in further detail below with reference to the drawings by means of specific embodiments. Wherein like elements in different embodiments are numbered alike in association. In the following embodiments, numerous specific details are set forth in order to provide a better understanding of the present application. However, one skilled in the art will readily recognize that some of the features may be omitted, or replaced by other elements, materials, or methods in different situations. In some instances, some operations associated with the present application have not been shown or described in the specification to avoid obscuring the core portions of the present application, and may not be necessary for a person skilled in the art to describe in detail the relevant operations based on the description herein and the general knowledge of one skilled in the art.

Furthermore, the described features, operations, or characteristics of the description may be combined in any suitable manner in various embodiments. Also, various steps or acts in the method descriptions may be interchanged or modified in a manner apparent to those of ordinary skill in the art. Thus, the various orders in the description and drawings are for clarity of description of only certain embodiments, and are not meant to be required orders unless otherwise indicated.

The numbering of the components itself, e.g. "first", "second", etc., is used herein merely to distinguish between the described objects and does not have any sequential or technical meaning. The terms "coupled" and "connected," as used herein, are intended to encompass both direct and indirect coupling (coupling), unless otherwise indicated.

In order to adapt to different medical situations, especially when medical staff needs to go out to a medical rescue place for medical rescue, in order to bring the medical staff to carry corresponding medical equipment according to the needs, please refer to fig. 1 and 2, a defibrillation monitoring device is provided in some embodiments of the present application. The defibrillation-monitoring device comprises a main machine 101 and a monitoring apparatus 201. The host 101 and the monitoring device 201 can be combined and split in a detachable connection mode, and when the user needs to go out to perform defibrillation and monitoring operation, the host 101 and the monitoring device 201 can be combined into a whole, so that the portable device is convenient to carry. The host 101 can independently complete defibrillation operation at the same time and can be at least used for displaying defibrillation information, so that the host 101 can be carried only to go to a medical rescue place when the defibrillation operation is required to be carried out independently. The monitoring device 201 can independently realize the monitoring function, and when the patient needs to go out to independently carry out the monitoring operation, the patient can only carry the monitoring device 201 to go to the medical rescue place. Therefore, the user can flexibly select the carried equipment according to the needs, and the convenience of use is improved.

In some embodiments, the host 101 includes a host housing 111, a host control unit, a host display unit 113 for displaying at least defibrillation information, a high voltage capacitor, a charging circuit, a discharging circuit, a host information transmission unit for information transmission, and the like. The host control unit, the high voltage capacitor, the charging circuit, and the discharging circuit are all housed in the host case 111, and are not shown in the drawings.

The main body housing 111 is a frame structure of the main body 101, the main body housing 111 may have a first accommodating cavity, and the main body control unit, the high voltage capacitor, the charging circuit and the discharging circuit are all located in the first accommodating cavity, so as to form an integral module. The main body housing 111 may be generally an outer shell of the main body 101, but in some embodiments, the housing may be at least partially not exposed, i.e. other structures may be provided outside the main body housing 111, such as a decorative shell or other structures, etc.

The high voltage capacitor is used to store electrical energy for defibrillation, the charging circuit is used for charging the electrical energy, and the discharging circuit is used for discharging the electrical energy to the patient. The host control unit controls the charging circuit and the discharging circuit to complete the charging and discharging process of the high-voltage capacitor and generate corresponding defibrillation information to realize the defibrillation function, which can comprise manual defibrillation and automatic defibrillation. The specific defibrillation principle is referred to the prior art and will not be described here too much.

In one embodiment, the host 101 may include a chest impedance detection circuit for obtaining chest impedance detection data. The host control unit receives the chest resistance detection data and controls the charging circuit and the discharging circuit to complete the charging and discharging process of the high-voltage capacitor.

Referring to fig. 1 and 2, in some embodiments, the host display unit 113 is disposed on the front side of the host housing 111. The front side is typically the side that faces the user when the host 101 is in normal use. Of course, in other embodiments, the host display unit 113 may be disposed on other sides of the host 101, such as the top or side of the host 101. The host display unit 113 may employ a pure display screen assembly only for displaying information, and at this time, the host 101 may configure physical or touch keys for instruction input and operation. Of course, in other embodiments, the host display unit 113 may also employ a touch screen assembly, so as to simultaneously display information and input instructions.

The host display unit 113 can be used to display defibrillation information (e.g., defibrillation energy, etc.) alone, and the host display unit 113 can also be used to display monitoring information (e.g., electrocardiograph, respiration, blood oxygen, etc.) after the host 101 is communicatively coupled to the monitoring device 201. The host 101 may be connected to the monitoring device 201 through a host information transmission unit by wire and/or wireless communication to implement unidirectional or bidirectional information transmission. The unidirectional information transmission may be unidirectional transmission of information from the monitoring device 201 to the host 101 to transmit the monitored information to the host 101 or display the monitored information on the host display unit 113. The unidirectional information transmission may be that the host 101 transmits information to the monitoring device 201 in one direction. The two-way information transmission is that the host 101 and the monitoring device 201 mutually exchange information. In some embodiments, the host 101 may also be communicatively connected to other medical devices (e.g., ultrasound devices, etc.) to obtain other medical information and correspondingly display the medical information on the host display unit 113.

The monitoring device 201 can realize the monitoring function when being installed or not installed in the assembly structure, namely, the monitoring device 201 can be separated from the host 101 to independently complete the monitoring function, and can also be installed on the host 101 to cooperate with the host 101 to realize the monitoring function.

Compared with the existing method that the display module, the monitoring module and the defibrillation module are arranged as three combinable modules, the device has the advantages that the simplified module number is more convenient, and the device can be installed and fixed or carried to rescue on site, so that a user can balance flexibility and device management convenience. The monitoring device 201 capable of being used independently has the independent monitoring device display unit 215, can display information independently of the host 101, greatly improves portability, meets the scene requirement of monitoring only under most conditions, and is more accurately suitable for pre-hospital emergency scenes.

Moreover, the host 101 has a defibrillation function, so that the defibrillation treatment function can be independently used after the defibrillation treatment function is separated from the monitoring device 201, and the defibrillation treatment function can be more flexibly adapted to different emergency situations. The monitoring device 201 does not need to integrate the defibrillation function, and has lighter volume and weight and better portability.

The combination and disassembly mode of the host 101 and the monitoring device 201 can adopt up-down combination, left-right combination and front-back combination. The back side refers to a side of the host 101 facing away from the front side, the left side refers to a side corresponding to a left hand when the user faces the front side of the host 101, and the right side refers to a side corresponding to a right hand when the user faces the front side of the host 101.

In some embodiments, to be able to house the monitoring device 201, the main housing 111 has an expansion module mounting region 115, the expansion module mounting region 115 having a shape that is able to house at least a portion of the monitoring device 201, the expansion module mounting region 115 can be either a cavity structure or an L-shaped open structure, mounting platform, or other shape. In some embodiments, the expansion module mounting region 115 may also house other functional modules, such as an ultrasound module, a respiratory module, and the like.

In some embodiments, the monitoring device 201 is disposed in the expansion module mounting region 115 and is mounted on the mounting structure, and the monitoring device 201 can be disposed on at least one of the left side, the right side, the rear side, the upper side and the lower side of the host display unit 113 with reference to the host display unit 113. For example, in the embodiment shown in FIGS. 1-5, the monitoring device 201 is located on the rear side of the host display unit 113. In the embodiment shown in fig. 1 and 2, the host 101 and the monitoring device 201 are combined in a front-to-back manner to balance the overall device layout, so that the overall device height and the device width can be reduced.

Of course, in other embodiments, the monitoring device 201 may also be located on the front side of the host display unit 113.

In some embodiments, the monitoring device 201 is capable of accessing the expansion module mounting region 115 and/or removing from the expansion module mounting region 115 from at least one of the rear, left, right, upper and lower sides of the expansion module mounting region 115 in a removal direction. For example, in some embodiments, at least one of the front, rear, left, right, upper, and lower sides of the expansion module mounting region 115 is open, and the monitoring device 201 can be accessed into the expansion module mounting region 115 and/or removed from the expansion module mounting region 115 from at least one of the open sides, which is exposed or provided with an openable and closable covering structure. The shielding structure may employ, but is not limited to, a shielding cover or the like.

Referring to fig. 1 and 2, in some embodiments, the monitoring device 201 can be removed from the rear, upper, left, or right side of the expansion module mounting region 115. Referring to fig. 3, in some embodiments, the monitoring device 201 can be removed from the top, left, or right side of the expansion module mounting region 115.

Further, referring to FIGS. 1-5, in some embodiments, at least two sides of the mainframe housing 111 define an expansion module mounting area 115. When the monitoring device 201 is mounted to the mounting structure, the monitoring device 201 is at least partially received in the expansion module mounting region 115, i.e., the monitoring device 201 may be fully or partially received within the expansion module mounting region 115.

Referring to fig. 1, 2 and 5, in some embodiments, the main housing 111 has a support stand 116. The support table 116 includes a support surface 1161 and at least two surfaces of the main housing 111 defining the expansion module mounting region 115 include support surfaces 1161. The expansion module mounting region 115 is located on the upper side of the support table 116, and the support surface 1161 is used to support the monitoring device 201.

Specifically, referring to fig. 2, in some embodiments, the surface of the main housing 111 defining the extension module mounting area 115 includes a supporting surface 1161 and a side surface 1171 located on the front side of the extension module mounting area 115, where the supporting surface 1161 and the side surface 1171 enclose an L-shaped open structure to facilitate the mounting and the taking and placing of the monitoring module. The monitoring device 201 may be received and placed in the open configuration. The monitoring device 201 can be placed onto the support table 116 and/or removed from the support table 116 from at least one of the rear, left, right, and upper sides of the expansion module mounting region 115.

The face forming the main housing 111 defining the expansion module mounting region 115 may also include other faces, for example, referring to fig. 3-5, in one embodiment, the back end of the support stand 116 may also have an upwardly convex back side 118, the front side 1181 of the back side 118 together with the support surface 1161 and the side 1171 enclosing an expansion module mounting region 115, the monitoring device 201 may be received within the expansion module mounting region 115, and the monitoring device 201 may be removed from the upper, left and/or right sides of the expansion module mounting region 115. Further, the other surface may be a surface located on the left or right side of the expansion module mounting region 115.

Further, referring to fig. 1-5, in some embodiments, the support stand 116 is located at the rear side of the host display unit 113, so that the monitoring device 201 can be prevented from occupying the space of the front host display unit 113, ensuring that the host display unit 113 has a sufficient display area, and realizing display of a larger area.

Further, when the host display unit 113 is located on the front side of the host 101, for more convenient viewing, please refer to fig. 2, in an embodiment, when the defibrillation-monitoring device is horizontally placed, the host display unit 113 forms a first angle a with respect to the vertical direction, and the first angle a enables the display surface of the host display unit 113 to form an elevation angle, so that the user can conveniently view the display surface at a higher position.

In addition, referring to fig. 2, in one embodiment, the supporting surface 1161 is inclined downward at a first angle a along a direction from front to back in cooperation with the first angle a. The first angle a can enable the monitoring device 201 to be set back in an elevation angle, so that the monitoring device 201 is more convenient to install and detach. Of course, the downward inclination of the supporting surface 1161 may deviate from the first angle a by a small amount, for example, within 5 degrees, as long as the installation of the monitoring device 201 is not affected.

Further, in order to achieve the communication connection between the host 101 and the monitoring device 201, the host information transmission unit may select a communication unit with a physical docking portion and/or a wireless communication unit (such as WIFI, bluetooth, cellular data, etc.) that achieves wireless communication. Correspondingly, the monitoring device 201 has a monitoring module information transmission unit consistent with the host information transmission unit, and the monitoring module information transmission unit may select a communication unit with a physical docking portion and/or a wireless communication unit for implementing wireless communication. The host 101 and the monitoring device 201 not only can utilize the host information transmission unit and the monitoring module information transmission unit to realize communication connection, but also can respectively realize communication connection with other devices through the host information transmission unit and the monitoring module information transmission unit, for example, data unidirectional transmission or data interaction with the in-hospital device can be realized. When the host 101 and the monitoring device 201 are separated, if the information is to be continuously transmitted, the information can be realized by wireless communication.

The host information transfer unit may also be used as a power source, for example, to power the monitoring device 201 through the host 101, or vice versa, to power the host 101 by the monitoring device 201. When the host information transmission unit and/or the monitoring module information transmission unit are used as power supply components, the wireless charging mode can be realized, and the wired connection mode can also be realized. Of course, a charging circuit may be provided on the host 101 and the monitoring device 201 to realize charging.

Referring to fig. 2 and 5, in one embodiment, the host information transmission unit includes a docking portion 119 for connecting to the monitoring device 201, and the docking portion 119 is disposed on a side 1171 located on the front side of the expansion module mounting region 115. The interface 119 may be a metal contact, interface, or other type of physical interface 119. Correspondingly, the monitoring module information transmission unit also has a second docking portion 119 adapted to the docking portion 119. The second docking portion 119 may contact the docking portion 119 when the monitoring device 201 is installed into the expansion module installation region 115 to enable data communication. For example, in the embodiment shown in fig. 2, the mating portion 119 and the second mating portion 217 are metal contacts; in the embodiment shown in fig. 5, the docking portion 119 is a socket, and in this case, the second docking portion 217 may be a socket of the same specification.

In addition, the docking portion 119 may be disposed on other sides of the expansion module mounting region 115, such as on a bottom surface (e.g., the support surface 1161) of the expansion module mounting region 115, or the docking portion 119 may be disposed on a front side 1181 of the rear side 118 as in the embodiment of fig. 3 and 4.

In order to prevent the monitoring module from falling off the host 101, the host 101 and the monitoring device 201 are detachably assembled, the host housing 111 is provided with an assembling structure 120, and the monitoring device 201 can be detachably mounted on the assembling structure 120. The assembly structure 120 may have, but is not limited to, a snap-fit structure, a magnetic fixation, a removable adhesive structure, a screw fixation structure, a tight-fit structure, etc.

In an exemplary configuration, referring to fig. 5, the docking structure includes a latch 121 and an unlatch 122. The latch 121 is disposed to protrude toward the extension module mounting area 115, and in the figure, the latch 121 is disposed upward, so that a snap-fit structure can be formed with the latch 121 when the monitoring module is mounted to the extension module mounting area 115 from top to bottom. The unlocking piece 122 and the lock catch 121 form a linkage structure, and the lock catch 121 can be driven to move by controlling the movement of the unlocking piece 122, so that a user can drive the lock catch 121 to move in a direction away from the monitoring module through the unlocking piece 122, and the locking state of the lock catch 121 and the monitoring module is released. If the unlocking piece 122 drives the lock catch 121 to move downwards so as to be separated from the buckling structure on the monitoring module, the monitoring module can be conveniently taken away at the moment.

The latch 121 may be disposed on any at least one of the faces that form the expansion module mounting region 115, such as in FIG. 5, the latch 121 being disposed on a face that faces the expansion module mounting region 115, such as the side 1171. In addition, the latch 121 may be provided on the bottom surface or other surfaces.

The unlocking member 122 and the locking catch 121 may be provided on the same face or on two adjacent faces, respectively, for example, in fig. 5, the unlocking member 122 and the locking catch 121 are provided on two adjacent faces of the side portion 117. The unlocking piece 122 may be located on the top surface of the side 117, and the lock catch 121 is disposed on the side 1171 of the side 117, so that the lock catch 121 is convenient to lock the monitoring module, and a user can trigger the unlocking piece 122 to unlock. In addition, the unlocking member 122 and the locking member 121 may be disposed on the same surface or adjacent surfaces of the support base 116, for example, on the support surface 1161 of the support base 116. The unlocking member 122 and the lock catch 121 may also be provided on adjacent faces of the support table 116 and the side portion 117. Of course, the unlocking member 122 and the lock catch 121 may be disposed on different surfaces of the host 101 that are not adjacent to each other, in addition to two adjacent surfaces.

Of course, the above is only one exemplary case of the latch 121, the unlocking member 122, or the entire assembly structure, and in other embodiments, other assembly structures capable of achieving locking and unlocking may be employed.

Further, the monitoring device 201 can be used alone or assembled with the host 101 as a separate integral module from the host 101. Typically, the monitoring device 201 includes monitoring accessories that may include sensors and cables for at least one of electrocardiographic, blood oxygen, non-invasive blood pressure, body temperature, and exhaled air, often without being housed in a targeted manner or in a separate case. When not stored pertinently, the accessories are placed in disorder, and occupy the space of the medical place (such as the space in an ambulance, etc.) which is already very limited. When housed in a separate case, the monitoring accessory and the monitoring device 201 are inconvenient to carry, causing inconvenience to the user.

In contrast, referring to fig. 6-13, in some embodiments, the monitoring device 201 is further provided with a first receiving member 301. The first receiving member 301 can be used for receiving monitoring accessories (such as sensors and connection cables), so as to avoid the monitoring accessories from being placed in disorder to occupy the limited space and to avoid affecting the work of the user. The first receiving member 301 is detachably connected to the monitoring device 201, and is not detachably and fixedly connected to the monitoring device or integrally formed therewith. The first storage member 301 can be transferred together with the monitoring accessory and the monitoring device 201, which is convenient for the user to carry.

The releasable connection includes, but is not limited to, snap-fit, magnetic, releasable adhesive, etc. The non-detachable securing connection may include, but is not limited to, suture securing, non-detachable bonding, welding (e.g., ultrasonic welding), and the like. The first receiving member 301 may be a box made of fabric material, or may be a plastic box or other material.

The monitoring device 201 at least comprises a monitoring module 211, and the monitoring module 211 is used for realizing a monitoring function. The monitoring module 211 has a monitoring module housing 213, a monitoring module control unit for receiving and processing monitoring data, a monitoring module display unit 215 for displaying monitoring data, the monitoring module information transmission unit described above, and other related components, i.e., the monitoring module 211 can independently perform monitoring detection and monitoring information display functions. The monitoring module control unit and the monitoring module information transmission unit may be installed in the monitoring module housing 213, and the monitoring module display unit 215 may be exposed from the monitoring module housing 213 to display the monitoring information. The monitoring module control unit is disposed within the monitoring module housing 213 and is not shown.

The monitoring device 201 may mainly have a monitoring module 211, where the first receiving member 301 may be detachably connected, non-detachably fixed connected or integrally formed with the monitoring module 211. The first receiving member 301 can be transferred together with the monitoring accessory and the monitoring module 211, which are convenient for the user to carry.

The monitoring module 211 has a first docking structure for detachable connection with the mounting structure 120. The first docking structure corresponds to the assembly structure 120 of the host 101, and may have, but is not limited to, a snap-fit structure, a magnetic fixation, a detachable adhesive structure, a screw fixation structure, a tight-fit structure, etc. By the first docking structure, the monitoring module 211 can be directly mounted on the host 101, thereby being integrated with the host 101 for portability. In this embodiment, by directly detachably connecting the monitoring module 211 with the host 101, the volume of the monitoring device 201 can be reduced, and thus the space of the host 101 for accommodating the monitoring device 201 can be reduced, which is beneficial to further reducing the volume of the host 101.

In one embodiment, the first receiving member 301 can be directly detachably connected to the monitoring module 211, so as to realize an integrated structure with the monitoring module 211, so that the monitoring module 211 and the first receiving member 301 can move together to conveniently receive the accessory of the monitoring module 211.

In other embodiments, referring to fig. 6-13, the monitoring device 201 further includes a second receiving member 203, where the second receiving member 203 has a receiving cavity 2031 for receiving the monitoring module 211 and a second docking structure for detachably connecting with the mounting structure 120. The receiving cavity 2031 is configured to receive the monitoring module 211, and in these embodiments, the monitoring module 211 is detachably connected to the host 101 by the second receiving member 203. The second docking structure corresponds to the assembly structure 120 of the host 101, and the second docking structure may have, but is not limited to, a clamping structure, a magnetic fixing structure, a detachable adhesive structure, a screw fixing structure, a tight fitting structure, etc.

The second receiving member 203 is adopted for transferring, so that the monitoring module 211 only needs to be received in the second receiving member 203. The monitoring module 211 may not be provided with a first docking structure, so that the manufacturing difficulty of the monitoring module 211 may be reduced, and even the existing monitoring module 211 which does not have a detachable combination function with the host 101 may be directly combined with the host 101 through the second receiving member 203 without changing the structure of the existing monitoring module 211, thereby expanding the function of the existing monitoring module 211. The second receiving member 203 may be a case made of fabric material, or may be a plastic case or other material case. Generally, the second receiving member 203 may have an openable cover 2035 to facilitate the installation and removal of the monitoring module 211.

To facilitate information display of the monitoring module 211, in some embodiments, the monitoring module display unit 215 is not shielded by the second receiving member 203 when the monitoring module 211 is received in the receiving cavity 2031. For example, referring to fig. 6-8, in the illustrated embodiment, the second receiving member 203 has a window 2032 capable of exposing the display area of the monitor module display unit 215, and the window 2032 may be a through opening or a transparent area made of a transparent material. The area of the window 2032 is adapted to, and preferably equal to or greater than, the display area of the monitoring module display unit 215 so as to fully reveal the display area for the user to view information.

In addition to the physical space transfer function, the second receiving member 203 can also be used as a communication transfer structure between the monitoring module 211 and the host 101. For example, in some embodiments, the second receiving member 203 has an information transferring unit, the information transferring unit has a monitor module docking portion 2033 and a host docking portion 2035, the monitor module docking portion 2033 is configured to be communicatively connected to the monitor module information transmission unit of the monitor module 211, and the host docking portion 2035 is configured to be communicatively connected to the host information transmission unit of the host 101.

The information transfer unit may be a communication unit having a physical docking unit 119 and/or a wireless communication unit for realizing wireless communication. In some embodiments, the monitoring module docking portion 2033 and the host docking portion 2035 may each employ a metal contact, a plug interface, or other type of physical docking portion 119. The types of the monitor module docking portion 2033 and the host docking portion 2035 may be inconsistent, for example, since the monitor module 211 may be accommodated in the second accommodating member 203 for use, the monitor module docking portion 2033 may communicate with the monitor module 211 through a cable to ensure reliability of connection, and of course, may also communicate with the monitor module 211 through a metal contact, an interface, or the like. In order to achieve rapid docking between the second storage member 203 and the host 101, a structure capable of achieving rapid docking, such as a metal contact, an interface, or the like, may be selected. Of course, in other embodiments, the host docking portion 2035 may also be configured to be more reliably connected to the host 101 by a cable.

Of course, when the host 101 and the monitoring module 211 are connected by wireless communication, in some embodiments, the second housing member 203 may not have a communication transfer function. Of course, the wireless communication connection between the host 101 and the monitoring module 211 does not conflict with the communication transfer function of the second receiving member 203, and may also have both functions in some embodiments.

The information transfer unit may also be used as a power supply transfer unit, for example, the host 101 may supply power to the monitoring module 211 through the information transfer unit, or vice versa, the monitoring module 211 may supply power to the host 101 through the information transfer unit. When the information transfer unit is used as a power supply component, the information transfer unit can be realized in a wireless charging mode or in a wired connection mode. Of course, charging circuits may be provided on the host 101, the second receiving member 203, and the monitoring device 201 to realize charging.

The second receiving member 203 and the monitoring module 211 form a unitary structure, and a user can move the second receiving member 203 and the monitoring module 211 together. Referring to fig. 7, the second accommodating member 203 can accommodate not only the monitoring module 211 but also some cables 2036 of the monitoring module 211, where the cables 2036 may be accessory cables or other cables, such as power lines, signal lines, etc.

Of course, in one embodiment, the second receiving member 203 may include a plurality of separated sub receiving members, and the plurality of sub receiving members are integrally formed, non-detachably connected, or detachably connected. The sub-containers are divided into different spaces so as to be able to receive different articles separately. Of course, as shown in fig. 6 and 7, in some embodiments, the second receiving member 203 may also have only one receiving cavity 2031 for receiving the monitoring module 211 and a portion of the cable thereof.

Referring to fig. 6-13, in some embodiments, the first receiving member 301 and the second receiving member 203 are detachably connected, non-detachably fixed connected, or integrally formed. Through the second accommodating member 203, the first accommodating member 301 and the monitoring module 211 form an integrated structure, so that the monitoring module 211 and the first accommodating member 301 can move together, thereby accommodating the accessory of the monitoring module 211 conveniently.

Further, in some embodiments, the first receiving member 301 may be located on at least one of the rear side, the left side and the right side of the monitoring device 201, so as to reserve a space on the front side of the monitoring device 201, so that the monitoring device 201 can dock with the host 101 from the front side, the docking manner is more consistent with the usage habit of the user, and the front-back combination of the host 101 and the monitoring device 201 is also beneficial to reducing the size of the whole defibrillation monitoring device in the left-right direction, so as to avoid occupying an excessive space in the width direction in the medical place. Of course, in some embodiments, when the combination of the monitoring device 201 and the host 101 is not blocked, the first receiving member 301 may also be disposed on the front side of the monitoring device 201.

For example, in some embodiments, when the first receiving member 301 is disposed on the monitoring module 211, the first receiving member 301 is disposed on the left and right sides of the monitoring module 211, so as to form a balanced structure. Referring to fig. 6-13, in other embodiments, when the first receiving member 301 is disposed on the second receiving member 203, the first receiving member 301 is disposed on the left and right sides of the second receiving member 203, so as to form a left-right balanced structure. When the monitoring module 211 and the first accommodating member 301 are separated from the host 101 and used alone, the two structures are beneficial to concentrating the gravity center on the monitoring module 211 and the second accommodating member 203, so that the portable and usable monitor is more convenient.

Referring to fig. 6 to 13, in some embodiments, the first accommodating member 301 is separately disposed on the left and right sides of the monitor device 201, and does not occupy the front-rear space of the monitor device 201, and the first accommodating member 301 can be designed to be larger or smaller according to the needs in the front-rear matching manner of the monitor device 201 and the host 101, so that the volume of the first accommodating member 301 is not affected by the volumes of the host 101 and the monitor device 201, and is more flexible.

Of course, each first receiving member 301 may also include a plurality of separated sub receiving members, and the plurality of sub receiving members are integrally formed, non-detachably connected to each other. Through these sub-storage parts, can be with the storage of various guardianship annex classification, can more convenient management and take the guardianship annex that needs. In other embodiments, each first receiving member 301 may have only one receiving cavity for receiving the monitoring accessory.

Referring to fig. 7 and 8, in some embodiments, on a cross section of the defibrillation monitoring apparatus perpendicular to the bottom surface along the front-back direction, the projection of the first receiving member 301 at least partially coincides with the projection of the main unit 101, at this time, the front side of the first receiving member 301 protrudes out of the second receiving member 203 (may also be the monitoring module 211), so that the second receiving member 203 (may also be the monitoring module 211) and the first receiving member 301 form a concave structure, and the concave structure is used for jogging the main unit 101. The concave structure fully utilizes the space on two sides of the host 101 and the monitoring device 201 to set the first containing piece 301, so that the first containing piece 301 can be designed to be larger, more monitoring accessories can be contained, the first containing piece 301 can be ensured not to occupy the space of the host 101 and the monitoring device 201, and the host 101 and the monitoring device 201 can be kept in normal butt joint.

In order to achieve the above-mentioned concave structure, please refer to fig. 7, in an embodiment, the second receiving member 203 (may also be the monitoring module 211) has a larger left-right width, the horizontal cross section of the first receiving member 301 is square, and the first receiving members 301 on two sides are fixed on two sides of the second receiving member 203 (may also be the monitoring module 211), so as to form the concave structure. Referring to fig. 8, in another embodiment, the left-right width of the second receiving member 203 (may also be the monitoring module 211) is smaller, the horizontal section of the first receiving member 301 is L-shaped, the first receiving members 301 on both sides are fixed on both sides of the second receiving member 203 (may also be the monitoring module 211), and this combination form can make the first receiving member 301 on both sides more fully use the space on both sides of the second receiving member 203 (may also be the monitoring module 211), so as to skillfully increase the storage space of the first receiving member 301 without changing the transverse width of the whole module.

Of course, in other embodiments, the projection of the first receiving member 301 does not overlap with the projection of the main unit 101 or overlaps with the projection portion of the main unit 101 in a cross section of the defibrillation monitoring apparatus perpendicular to the bottom surface in the left-right direction.

In general, the monitoring device 201 is further provided with an electrode sheet 410 and an electrode sheet cable 420, and the electrode sheet 410 and the electrode sheet cable 420 can be accommodated in the first accommodating member 301 or the second accommodating member 203. Considering that the electrode sheet 410 is generally in a sheet-like structure, in order to avoid excessively bulky first receiving member 301 or second receiving member 203, in some embodiments, a third receiving member 302 may be further included, where the third receiving member 302 is configured to receive the electrode sheet 410 and/or the electrode sheet cable 420. Of course, the third receiving member 302 may be used to receive other accessories as needed in addition to the electrode tab 410 and/or the electrode tab cable 420.

The third receiving member 302 is detachably connected to the monitoring device 201 or detachably connected to the host 101, and is not detachably fixedly connected to the host or integrally formed with the host.

As shown in fig. 11-15, in some embodiments, when the third receiving member 302 is used for receiving the electrode sheet 410, the third receiving member 302 may have a sheet structure similar to the electrode sheet 410, so as to reduce the thickness and avoid bulkiness. As shown in fig. 16 and 17 and fig. 19 and 20, in some embodiments, when the third receiving member 302 is used for receiving the electrode sheet cable 420, the third receiving member 302 may be designed to be smaller and more compact enough to receive the electrode sheet cable 420.

The third receiving member 302 may be disposed on the host 101 or the monitoring device 201, but since the electrode pad 410 is generally used with the host 101, in some embodiments, the third receiving member 302 is preferably disposed on the host 101. For example, referring to fig. 14-17, in these embodiments, the third receiving member 302 is disposed on the host 101.

In order to achieve a more compact structure, the third receiving member 302 is provided on the side 1171 located on the front side of the expansion module mounting region 115 and/or on the rear side of the support stand 116. Specifically, referring to fig. 14, in this embodiment, the third receiving member 302 is disposed at the rear side of the supporting table 116, and the third receiving member 302 can not only receive the electrode sheet 410 and/or the electrode sheet cable 420, but also enclose the rear side of the monitoring device 201 to form the expansion module mounting region 115. Referring to fig. 15, in this embodiment, the third receiving member 302 is disposed on the side 1171 of the front side of the expansion module mounting region 115, so that the space of the expansion module mounting region 115 is fully utilized, and the third receiving member 302 is not required to be additionally disposed at other positions. Referring to fig. 16, 17 and 20, the third receiving member 302 is also disposed at the rear side of the supporting table 116, and the third receiving member 302 is used for receiving the electrode cable 420. At this time, the height of the third receiving member 302 may be designed to be lower, if the electrode sheet 410 is not to be received. In these embodiments, the third receiving member 302 is disposed parallel to the host display unit 113.

In addition, the third receiving member 302 may be disposed at other positions of the host 101, for example, at two sides of the host 101. Referring to fig. 19, in one embodiment, the third receiving member 302 is disposed on the left and right sides (or one side) of the host 101.

When the third accommodating member 302 is used for accommodating the electrode sheet cable 420, an electrode sheet accommodating cavity may be further disposed on the host 101 for accommodating the electrode sheet 410. For example, referring to fig. 18 and 19, in these embodiments, an electrode sheet receiving cavity may be provided at the bottom of the host 101, the electrode sheet receiving cavity being open toward the front side for inserting and removing the electrode sheet 410. For another example, referring to fig. 20, in this embodiment, a side 117 of the host 101 facing the expansion module mounting region 115 may be provided with an electrode sheet receiving cavity that is opened upward for inserting and removing the electrode sheet 410. Referring to fig. 16, 17 and 20, in some embodiments, the electrode pad receiving cavity may be further disposed at the rear of the main body 101, and the electrode pad receiving cavity is opened toward the front side for inserting and removing the electrode pad 410. In addition, the electrode sheet receiving chamber may be provided at other positions of the main body 101.

When the third storage member 302 for storing the electrode sheet cable 420 is provided, the electrode sheet cable 420 and the host 101 are also pre-connected, and no connection is required in the field during emergency treatment.

In addition, the third receiving member 302 may also be disposed on the monitoring device 201. Referring to fig. 11-13, in these embodiments, the third receiving member 302 is disposed at the rear side of the second receiving member 203 (or the monitoring module 211). The third receiving member 302 is detachably connected to the second receiving member 203 (or the monitoring module 211) so as to be detachable for use at any time.

Of course, the third receiving member 302 may be disposed at another position of the second receiving member 203 (may be the monitoring module 211) or disposed on the first receiving member 301.

Further, the present application also provides a monitoring assembly that includes a monitoring module 211 and a second housing 203. The monitoring module 211 and the second receiving member 203 may have the structures described in the above embodiments. The second receiving member 203 has a function of receiving the monitoring module 211, i.e., the monitoring module 211 can be placed in the second receiving member 203. The second receiving member 203 further has a second docking structure by which the second receiving member 203 together with the monitoring module 211 can be mounted to other devices, such as the host 101 or other devices described above, so that the monitoring module 211 can be removably combined with the other devices.

Further, another monitoring assembly is provided, which includes a monitoring module 211 and a first receiving member 301, where the monitoring module 211 and the first receiving member 301 may adopt the structures shown in the foregoing embodiments. The first receiving member 301 is detachably connected to the monitoring module 211, and is not detachably and fixedly connected to the monitoring module or integrally formed with the monitoring module. The first receiving member 301 can be used for receiving monitoring accessories (such as sensors and connection cables), so as to avoid the monitoring accessories from being placed in disorder to occupy the limited space and to avoid affecting the work of the user.

On the other hand, in some embodiments of the present application, there is also provided a defibrillation-monitoring device, which is different from the defibrillation-monitoring device shown in the above embodiments in that the defibrillation-monitoring device includes the display device 102 and the defibrillation-monitoring device 202. The display device 102 is mainly used for displaying information, and the defibrillation monitoring device 202 includes a defibrillation monitoring integrated machine 212, and the defibrillation monitoring integrated machine 212 can independently complete monitoring and defibrillation operation. Of course, the display device 102 may be used for display purposes to display defibrillation information and monitoring information. In some embodiments, the display device 102 may also be used to control the defibrillation-monitoring kiosk 212 to perform monitoring and/or defibrillation operations.

Referring to fig. 1-20, in the embodiments shown, the display device 102 may have the same or similar shape and structure as the host 101, so that the two are labeled together, and other labeled together are understood below. The defibrillation-monitoring device 202 may have the same or similar shape and configuration as the monitoring device 201, and the defibrillation-monitoring integrated machine 212 may have the same or similar shape and configuration as the monitoring module 211.

The display device 102 includes a display device housing 112 (in the embodiment shown in fig. 1 to 20, the display device housing 112 may have the same or similar shape and structure as the host housing 111), a display device display unit 114 (in the embodiment shown in fig. 1 to 20, the display device display unit 114 may have the same or similar shape and structure as the host display unit 113), and a display device information transmission unit for information transmission (the display device information transmission unit adopts the same or similar structure as the host information transmission unit described above).

In one embodiment, the defibrillation monitoring unit 212 includes a unit housing 214 (in the embodiment shown in fig. 1-20, the unit housing 214 may have the same or similar shape and structure as the monitoring module housing 213), a unit display unit 216 for displaying information (in the embodiment shown in fig. 1-20, the unit display unit 216 may have the same or similar shape and structure as the main housing 111), a high voltage capacitor, a chest impedance detection circuit, a charging circuit, a discharging circuit, a unit information transmission unit for information transmission, a monitoring parameter circuit, and a unit control unit.

The integrated machine housing 214 has a second accommodating cavity, and the high-voltage capacitor, the charging circuit, the discharging circuit, the integrated machine information transmission unit, the integrated machine control unit and the monitoring parameter circuit are all located in the second accommodating cavity, so they are not shown in the drawings. The display device display unit 114 is disposed on the front side of the display device housing 112, and the display device display unit 114 is used for displaying the defibrillation information and the monitoring information transmitted by the defibrillation monitoring device 202.

In one embodiment, the defibrillation monitoring unit 212 may include a chest impedance detection circuit for obtaining chest impedance detection data. The control unit of the all-in-one machine receives chest resistance detection data and controls the charging circuit and the discharging circuit to complete the charging and discharging process of the high-voltage capacitor.

The information transmission unit of the all-in-one machine can adopt the same or similar structure as the information transmission unit of the monitoring module in each embodiment. The information transmission unit of the all-in-one machine can be in communication connection with the information transmission unit of the display device so as to realize unidirectional or bidirectional information transmission. The all-in-one control unit is also used to control the all-in-one display unit 216 to display defibrillation information and monitoring information.

The defibrillation-monitoring device 202 is capable of performing both defibrillation and monitoring functions, both when mounted and when not mounted to the mounting structure 120. The defibrillation-monitoring integrated machine 212 is capable of independently performing a monitoring operation and a defibrillation operation. The display housing 112 has a mounting structure 120. When a larger display window is desired for display, the display device 102 and the defibrillation-monitoring device 202 may be combined into a single unit for use, with the defibrillation information and the monitoring information being displayed by the display device 102. However, when the weight and volume of the apparatus need to be reduced, the user can only carry the defibrillation monitoring apparatus 202 to go to the medical assistance site, and the information can be displayed by the integral display unit 216 of the defibrillation monitoring apparatus 202. Therefore, the user can flexibly select the carried equipment according to the needs, and the convenience of use is improved.

The display device 102 and the mounting structure 120 may employ the mounting structure 120 shown in the above embodiments. The defibrillation-monitoring device 202 can be removably mounted to the mounting structure 120 to enable removable combination of the display device 102 and the defibrillation-monitoring device 202. The detachable connection and combination of the display device 102 and the defibrillation monitoring device 202 can be the detachable connection and combination of the host 101 and the monitoring device 201 in the above embodiments.

For example, the defibrillation-monitoring device 202 may also employ the first docking structure described in the above embodiments to dock with the mounting structure 120 of the display device 102.

For another example, the display device 102 may have an extension module mounting area 115 as shown in the various embodiments described above, with the defibrillation-monitoring device 202 being at least partially received within the extension module mounting area 115 when the defibrillation-monitoring device 202 is mounted to the mounting structure 120.

Further, referring to fig. 6-20, in some embodiments, the defibrillation-monitoring device 202 further includes a first receiving member 301, where the first receiving member 301 is configured to receive an accessory for defibrillation and/or monitoring, and is detachably connected, fixedly connected, or integrally formed with the defibrillation-monitoring device 202. The first receiving member 301 can be used for receiving defibrillation and/or monitoring accessories (such as sensors and connection cables for monitoring, electrode pads 410 for defibrillation, electrode pads, etc.), so as to avoid the accessories from being placed in disorder and occupying the space and affecting the work of the user. The first storage element 301 may be the first storage element 301 shown in the above embodiments.

Further, referring to fig. 6-20, in some embodiments, the defibrillation-monitoring device 202 further includes a second receiving member 203, where the second receiving member 203 has a machine receiving space for receiving the defibrillation-monitoring machine 212 and a second docking structure for detachably connecting with the mounting structure 120. The second receiving member 203 may be the second receiving member 203 shown in the above embodiments. The second storage member 203 may also have an information transfer unit, where the information transfer unit has an integrated machine docking portion 2034 and a display device docking portion 2036, where the integrated machine docking portion 2034 is configured to be communicatively connected to an integrated machine information transmission unit of the defibrillation monitoring integrated machine 212, and the display device docking portion 2036 is configured to be communicatively connected to the display device information transmission unit.

Further, referring to fig. 11-20, in some embodiments, a third receiving member 302 is further included, where the third receiving member 302 is configured to receive the electrode sheet 410 and/or the electrode sheet cable 420. The third receiving member 302 is detachably connected, non-detachably fixedly connected, or integrally formed with the defibrillation-monitoring device 202 or the display device 102. The third receiving member 302 may be the third receiving member 302 shown in the above embodiments.

Further, the present application also provides a defibrillation-monitoring assembly comprising a defibrillation-monitoring unit 212 and a second receiving member 203, wherein the second receiving member 203 is provided with a housing for receiving the defibrillation-monitoring unit 212, i.e. the defibrillation-monitoring unit 212 is placed in the second receiving member 203. The second receiving member 203 further has a second docking structure, through which the second receiving member 203 together with the integrated defibrillation-monitoring unit 212 can be mounted on other devices, such as the display device 102 described above, so that the integrated defibrillation-monitoring unit 212 can form a detachable combination with other devices.

Further, another defibrillation monitoring assembly is provided, which includes a defibrillation monitoring integrated machine 212 and a first receiving member 301, wherein the first receiving member 301 is detachably connected, non-detachably fixedly connected or integrally formed with the defibrillation monitoring integrated machine 212. The first receiving member 301 can be used for receiving defibrillation and/or monitoring accessories (such as sensors and connection cables for monitoring, electrode pads 410 for defibrillation, electrode pads, etc.), so as to avoid the accessories from being placed in disorder and occupying the space and affecting the work of the user.

The foregoing description of the invention has been presented for purposes of illustration and description, and is not intended to be limiting. Several simple deductions, modifications or substitutions may also be made by a person skilled in the art to which the invention pertains, based on the idea of the invention.

Claims (73)

1. A defibrillation monitoring device, comprising:

the host comprises a host shell, a host control unit, a host display unit, a high-voltage capacitor, a charging circuit, a discharging circuit and a host information transmission unit for information transmission, wherein the host display unit is at least used for displaying defibrillation information;

the host control unit controls the charging circuit and the discharging circuit to complete the charging and discharging process of the high-voltage capacitor and generate corresponding defibrillation information;

the host shell is provided with a first accommodating cavity, the host control unit, the high-voltage capacitor, the charging circuit and the discharging circuit are all positioned in the first accommodating cavity, and the host display unit is arranged on the front side of the host shell;

the monitoring device can be detachably arranged on the assembly structure; the monitoring device can realize the monitoring function when being arranged and not arranged in the assembly structure, and the host is in communication connection with the monitoring device through the host information transmission unit so as to realize unidirectional or bidirectional information transmission; and

The first storage piece is used for storing the monitoring accessory and is detachably connected with the monitoring device, and is not detachably fixedly connected with the monitoring device or integrally formed with the monitoring device.

2. The defibrillation monitoring device of claim 1, wherein at least two faces of the main housing define an extension module mounting region; when the monitoring device is mounted to the mounting structure, the monitoring device is at least partially received in the expansion module mounting area.

3. The defibrillation monitoring device of claim 1 or 2, wherein the monitoring device is located on at least one of the left, right, rear, upper and lower sides of the main unit display unit when the monitoring device is mounted to the mounting structure.

4. The defibrillation monitoring apparatus of claim 3, wherein the monitoring device is located on a rear side of the host display unit when the monitoring device is mounted to the mounting structure.

5. The defibrillation monitoring device of claim 3 or 4, wherein the monitoring apparatus is capable of entering and/or being removed from the extension module mounting area from at least one of a rear side, a left side, a right side, an upper side, and a lower side of the extension module mounting area.

6. The defibrillation monitoring device of claim 3 or 4, wherein at least one of the rear, left, right, upper and lower sides of the extension module mounting area is open, the monitoring apparatus being capable of being accessed and/or removed from the extension module mounting area from at least one of the open sides, the at least one of the open sides being exposed or provided with an openable and closable covering structure.

7. The defibrillation monitoring device of claim 2, wherein the main housing has a support table, the support table including a support surface, at least two surfaces of the main housing defining the extension module mounting area including the support surface; the expansion module installation area is positioned on the upper side of the supporting table, and the supporting surface is used for supporting the monitoring device.

8. The defibrillation monitoring device of claim 7, wherein the support stand is located at a rear side of the main display unit, and the monitoring apparatus is capable of being placed on and/or removed from the support stand from at least one of a rear side, a left side, a right side, and an upper side of the extension module mounting area.

9. The defibrillation monitoring device of claim 7, wherein the main display unit forms a first angle with the vertical when the defibrillation monitoring device is horizontally placed, and the support surface is inclined downward at the first angle in a front-to-back direction in cooperation with the first angle.

10. The defibrillation monitoring device of claim 2, wherein at least two faces of the main housing defining the extension module mounting area include sides located on a front side of the extension module mounting area, the main information transmission unit including a docking portion for connecting the monitoring unit, the docking portion being provided on the sides located on the front side of the extension module mounting area.

11. The defibrillation monitoring device of any one of claims 1-10, wherein the host comprises a chest impedance detection circuit for obtaining chest impedance detection data, the host control unit receiving the chest impedance detection data and controlling the charging circuit and the discharging circuit to complete the charging and discharging of the high voltage capacitor.

12. The defibrillation monitoring device of any one of claims 1-11, wherein the monitoring means comprises a monitoring module having a monitoring module control unit for receiving and processing the monitored data, a monitoring module display unit for displaying the monitored data, and a monitoring module information transmission unit capable of being communicatively connected with the host information transmission unit to enable unidirectional or bidirectional information transmission.

13. The defibrillation monitoring device of claim 12, wherein the monitoring module has a first docking structure for detachable connection with the mounting structure.

14. The defibrillation monitoring device of claim 12, wherein the monitoring unit further comprises a second housing having a housing cavity for housing the monitoring module and a second docking structure for detachable connection with the mounting structure.

15. The defibrillation monitoring device of claim 14, wherein the monitoring module display unit is not obscured by the second housing when the monitoring module is housed in the housing cavity; the second storage piece is provided with an information transfer unit, the information transfer unit is provided with a monitoring module docking part and a host docking part, the monitoring module docking part is used for being in communication connection with a monitoring module information transmission unit of the monitoring module, and the host docking part is used for being in communication connection with a host information transmission unit of the host.

16. The defibrillation monitoring device of claim 14, wherein the second housing member includes a plurality of separate sub-housing members, the plurality of sub-housing members being integrally formed, non-detachably fixedly connected, or detachably connected therebetween.

17. The defibrillation monitoring device of claim 13, wherein the first housing member is removably coupled to the monitoring module.

18. The defibrillation monitoring device of claim 14, wherein the first housing member is detachably connected, non-detachably fixedly connected, or integrally formed with the second housing member.

19. The defibrillation monitoring device of any one of claims 1-18, wherein the first housing is located on at least one of a rear side, a left side, and a right side of the monitoring unit.

20. The defibrillation monitoring device of claim 19, wherein the first housing member is disposed on a left side and a right side of the monitoring module or the second housing member, respectively.

21. The defibrillation monitoring device of any one of claims 1-20, wherein the first housing member includes a plurality of separate sub-housing members, the plurality of sub-housing members being integrally formed, non-detachably fixedly connected, or detachably connected therebetween.

22. The defibrillation monitoring device of claim 1, wherein the projection of the first housing member at least partially coincides with the projection of the main body in a cross-section of the defibrillation monitoring device perpendicular to the bottom surface in the front-to-back direction.

23. The defibrillation monitoring device of claim 1, wherein the projection of the first housing member does not coincide with the projection of the main body or coincides with the projection portion of the main body in a cross section of the defibrillation monitoring device perpendicular to the bottom surface in the left-right direction.

24. The defibrillation monitoring device of claim 1, 7 or 10, further comprising a third housing for housing the electrode pad and/or the electrode pad cable;

the third storage piece is detachably connected with the monitoring device or the host machine, and is fixedly connected or integrally formed.

25. The defibrillation monitoring device of claim 24, wherein the third housing is disposed on the side located on the front side of the extension module mounting area and/or the rear side of the support table.

26. The defibrillation monitoring device of claim 24 or 25, wherein the third housing member is disposed in parallel with the main display unit.

27. A defibrillation monitoring device, comprising:

a display device including a display device housing, a display device display unit, and a display device information transmission unit for information transmission, the display device housing having an assembly structure;

And a defibrillation monitoring device detachably mountable to the mounting structure; and

the first storage piece is used for storing the accessories for defibrillation and/or monitoring and is detachably connected, non-detachably fixedly connected or integrally formed with the defibrillation monitoring device;

the defibrillation monitoring device comprises a defibrillation monitoring integrated machine, wherein the defibrillation monitoring integrated machine comprises an integrated machine shell, an integrated machine display unit for displaying information, a high-voltage capacitor, a chest resistance detection circuit, a charging circuit, a discharging circuit, an integrated machine information transmission unit for information transmission, a monitoring parameter circuit and an integrated machine control unit;

wherein,

the integrated machine information transmission unit can be in communication connection with the display device information transmission unit so as to realize unidirectional or bidirectional information transmission;

the monitoring parameter circuit is used for receiving vital sign data of a detected object and transmitting the vital sign data to the integrated machine control unit, and the integrated machine control unit generates corresponding monitoring information;

the integrated machine control unit controls the charging circuit and the discharging circuit to complete the charging and discharging process of the high-voltage capacitor and generate corresponding defibrillation information;

The integrated machine control unit is also used for controlling the integrated machine display unit to display the defibrillation information and the monitoring information;

the integrated machine shell is provided with a second accommodating cavity, the high-voltage capacitor, the charging circuit, the discharging circuit, the integrated machine information transmission unit, the integrated machine control unit and the monitoring parameter circuit are all positioned in the second accommodating cavity, and the integrated machine display unit is arranged in the integrated machine shell;

the defibrillation monitoring device can realize defibrillation function and monitoring function when being arranged and not arranged on the assembly structure; the display device is in communication connection with the defibrillation monitoring device through the display device information transmission unit so as to realize unidirectional or bidirectional information transmission;

the display unit of the display device is arranged on the front side of the display device shell and is used for displaying the defibrillation information and the monitoring information transmitted by the defibrillation monitoring device.

28. The defibrillation monitoring apparatus of claim 27, wherein at least two faces of the display device housing define an extension module mounting region; the defibrillation-monitoring device is at least partially received within the extension module mounting area when the defibrillation-monitoring device is mounted to the mounting structure.

29. The defibrillation monitoring apparatus of claim 27 or 28, wherein the defibrillation monitoring device is located on at least one of the left, right, rear, upper and lower sides of the display unit of the display device when the defibrillation monitoring device is mounted to the mounting structure.

30. The defibrillation monitoring device of claim 29, wherein the defibrillation monitoring apparatus is capable of entering and/or being removed from the extension module mounting area from at least one of a rear side, a left side, a right side, an upper side, and a lower side of the extension module mounting area.

31. The defibrillation monitoring device of claim 29 or 30, wherein at least one of the rear, left, right, upper and lower sides of the extension module mounting area is open, the defibrillation monitoring apparatus being capable of entering and/or being removed from the extension module mounting area from the open at least one side, the open at least one side being exposed or provided with an openable and closable covering structure.

32. The defibrillation monitoring apparatus of claim 30 or 31, wherein the display device housing has a support stand, the support stand including a support surface, at least two surfaces of the display device housing defining the extension module mounting area including the support surface; the extension module mounting area is positioned on the upper side of the supporting table, and the supporting surface is used for supporting the defibrillation monitoring device.

33. The defibrillation monitoring apparatus of claim 32, wherein the support stand is positioned on a rear side of the display unit of the display device, the defibrillation monitoring device being capable of being placed on and/or removed from the support stand from at least one of a rear side, a left side, a right side, and an upper side of the extension module mounting area.

34. The defibrillation monitoring apparatus of claim 32, wherein the display unit of the display device forms a first angle with the vertical when the defibrillation monitoring apparatus is horizontally placed, the supporting surface being inclined downward at the first angle in a front-to-back direction in cooperation with the first angle;

at least two faces of the display device housing defining the extension module mounting area include sides located on a front side of the extension module mounting area, and the display device information transmission unit includes a docking portion for connecting the defibrillation-monitoring device, the docking portion being located on the sides located on the front side of the extension module mounting area.

35. The defibrillation monitoring device of any one of claims 27-34, wherein the defibrillation monitoring unit has a first docking structure for detachable connection with the mounting structure.

36. The defibrillation monitoring device of any one of claims 27-34, wherein the defibrillation monitoring apparatus further comprises a second housing having a housing cavity for housing the defibrillation monitoring unit and a second docking structure for detachable connection with the mounting structure.

37. The defibrillation monitoring device of claim 36, wherein the integrated machine display unit is not obscured by the second housing member when the defibrillation monitoring integrated machine is housed in the housing cavity; the second storage piece is provided with an information switching unit, the information switching unit is provided with an integrated machine butt joint part and a display device butt joint part, the integrated machine butt joint part is used for being in communication connection with an integrated machine information transmission unit of the defibrillation monitoring integrated machine, and the display device butt joint part is used for being in communication connection with the display device information transmission unit.

38. The defibrillation monitoring device of claim 36, wherein the second housing member includes a plurality of separate sub-housing members, the plurality of sub-housing members being integrally formed, non-detachably fixedly connected, or detachably connected therebetween.

39. The defibrillation monitoring device of claim 37, wherein the first housing member is fixedly coupled to the defibrillation monitoring unit.

40. The defibrillation monitoring device of claim 36, wherein the first housing member is fixedly coupled to the second housing member.

41. The defibrillation monitoring device of claim 39 or 40, wherein the first housing member is located on at least one of a rear side, a left side, and a right side of the defibrillation monitoring device or the second housing member.

42. The defibrillation monitoring device of claim 39 or 40, wherein the first housing member is provided on both left and right sides of the defibrillation monitoring apparatus or the second housing member, respectively.

43. The defibrillation monitoring device of any one of claims 27-42, wherein the first housing member includes a plurality of separate sub-housing members fixedly connected or removably connected therebetween.

44. The defibrillation monitoring device of any one of claims 27-43, wherein the projection of the first housing member at least partially coincides with the projection of the display device in a cross-section of the defibrillation monitoring device in the front-to-back direction perpendicular to the bottom surface.

45. The defibrillation monitoring apparatus of any one of claims 39-43, wherein the projection of the first housing member does not coincide with the projection of the display device or coincides with the projection portion of the display device in a cross-section of the defibrillation monitoring apparatus perpendicular to the bottom surface in the left-right direction.

46. The defibrillation monitoring device of claim 27, 32 or 34, further comprising a third housing for housing the electrode pad and/or the electrode pad cable;

the third storage piece is detachably connected with the defibrillation monitoring device or the display device, and is not detachably fixedly connected or integrally formed.

47. The defibrillation monitoring apparatus of claim 46, wherein at least two faces of the display housing defining the extension module mounting area include sides located on a front side of the extension module mounting area, the third receptacle being disposed on the sides and/or a rear side of the stand.

48. The defibrillation monitoring device of claim 46 or 47, wherein the third housing member is disposed in parallel with the display unit of the display device.

49. The defibrillation monitoring device of any one of claims 27-48, wherein the display device includes a display device control unit capable of at least transmitting a defibrillation control signal to the all-in-one control unit to control the defibrillation monitoring device to defibrillate.

50. A monitoring assembly, comprising:

The monitoring module is provided with a monitoring module control unit for receiving and processing monitoring data, a monitoring module display unit for displaying the monitoring data and a monitoring module information transmission unit;

and the second storage part is provided with a storage cavity for storing the monitoring module and a second butt joint structure, and the second butt joint structure comprises a detachable bonding structure, a magnetic attraction fixing structure, a clamping structure and/or a screw joint fixing structure.

51. The monitoring assembly of claim 50, wherein the monitoring module display unit is unobstructed by the second receptacle when the monitoring module is received in the receiving cavity; the second storage piece is provided with an information switching unit, the information switching unit is provided with a monitoring module butting part and a host butting part, the monitoring module butting part is used for being in communication connection with the monitoring module information transmission unit, and the host butting part is used for being in communication connection with the host.

52. The monitoring assembly of claim 51, wherein the second housing comprises a plurality of separate sub-housings, the plurality of sub-housings being integrally formed, non-removably fixedly connected, or removably connected therebetween.

53. The monitoring assembly of any of claims 50-52, further comprising a first receiving member for receiving a monitoring accessory, the first receiving member being fixedly coupled to the second receiving member.

54. The monitoring assembly of claim 53, wherein the first housing member is positioned on at least one of a rear side, a left side, and a right side of the second housing member.

55. The monitoring assembly of claim 53, wherein the first receiving member is disposed on each of the left and right sides of the second receiving member.

56. The monitoring assembly of claim 53, wherein the first housing comprises a plurality of separate sub-housings, the plurality of sub-housings being fixedly connected or removably connected.

57. The monitoring assembly of claim 55, wherein the front side of the first receiving member protrudes from the second receiving member such that the second receiving member and the first receiving member form a concave structure for engaging a host.

58. A monitoring assembly, comprising:

the monitoring module is provided with a monitoring module control unit for receiving and processing monitoring data, a monitoring module display unit for displaying the monitoring data and a monitoring module information transmission unit; the monitoring module is provided with a first butt joint structure, and the first butt joint structure comprises a detachable bonding structure, a clamping structure and/or a screw joint fixing structure;

And the first storage piece is used for storing the monitoring accessory and is detachably connected with the monitoring module, and is non-detachably fixedly connected with the monitoring module or integrally formed with the monitoring module.

59. The monitoring assembly of claim 58, wherein at least one of the first receiving members is disposed on each of the left and right sides of the monitoring module.

60. The monitoring assembly of claim 59, wherein the front side of the first housing member protrudes from the monitoring module such that the first housing member and the monitoring module form a recessed structure for engaging a host.

61. The monitoring device of any of claims 58-60, wherein the first housing comprises a plurality of separate sub-housings, the plurality of sub-housings being removably connected, non-removably fixedly connected, or integrally formed.

62. The defibrillation monitoring assembly is characterized by comprising a defibrillation monitoring integrated machine and a second storage piece;

the defibrillation monitoring integrated machine comprises an integrated machine shell, an integrated machine display unit for displaying information, a high-voltage capacitor, a chest resistance detection circuit, a charging circuit, a discharging circuit, an integrated machine information transmission unit, an integrated machine control unit and a monitoring parameter circuit;

The integrated machine control unit controls the charging circuit and the discharging circuit to complete the charging and discharging process of the high-voltage capacitor;

the integrated machine information transmission unit can be connected with the display device to realize unidirectional or bidirectional information transmission;

the monitoring parameter circuit is used for receiving vital sign information of a detected object and transmitting the vital sign information to the control unit of the all-in-one machine;

the integrated machine control unit is also used for receiving and processing the vital sign information and the defibrillation instruction and controlling the integrated machine display unit to display corresponding defibrillation information and monitoring information;

the integrated machine shell is provided with a second accommodating cavity, and the high-voltage capacitor, the charging circuit, the discharging circuit, the integrated machine information transmission unit, the integrated machine control unit and the monitoring parameter circuit are all positioned in the second accommodating cavity;

the second storage piece is provided with a storage cavity for storing the defibrillation monitoring integrated machine; the second storage piece is provided with a second butt joint structure used for being detachably connected with the display device, and the second butt joint structure comprises a detachable bonding structure, a clamping structure and/or a screw fixing structure.

63. The defibrillation monitoring assembly of claim 62, wherein the integrated machine display unit is not obscured by the second housing member when the defibrillation monitoring integrated machine is housed in the housing cavity; the second storage piece is provided with an information switching unit, the information switching unit is provided with an integrated machine butt joint part and a display device butt joint part, the integrated machine butt joint part is used for being in communication connection with the integrated machine information transmission unit, and the display device butt joint part is used for being in communication connection with the display device.

64. The defibrillation monitoring assembly of claim 63, wherein the second housing includes a plurality of separate sub-housings detachably connected, non-detachably fixedly connected, or integrally formed therebetween.

65. The defibrillation monitoring assembly of any one of claims 62-64 further comprising a first housing member for housing an accessory for defibrillation and/or monitoring, the first housing member being fixedly coupled to the second housing member.

66. The defibrillation monitoring assembly of claim 65, wherein the first housing member is located on at least one of a rear side, a left side, and a right side of the second housing member.

67. The defibrillation monitoring assembly of claim 66, wherein the first housing member is disposed on each of the left and right sides of the second housing member.

68. The defibrillation monitoring assembly of claim 65, wherein the first housing member includes a plurality of separate sub-housing members, the plurality of sub-housing members being removably coupled, non-removably fixedly coupled, or integrally formed.

69. The defibrillation monitoring assembly of claim 67, wherein the front side of the first housing member protrudes from the second housing member such that the second housing member and the first housing member form a recessed structure for receiving a display device.

70. The defibrillation monitoring assembly is characterized by comprising a defibrillation monitoring integrated machine and a first storage piece;

the defibrillation monitoring integrated machine comprises an integrated machine shell, an integrated machine display unit for displaying information, a high-voltage capacitor, a chest resistance detection circuit, a charging circuit, a discharging circuit, an integrated machine information transmission unit, an integrated machine control unit and a monitoring parameter circuit;

the integrated machine control unit controls the charging circuit and the discharging circuit to complete the charging and discharging process of the high-voltage capacitor;

the integrated machine information transmission unit can be in communication connection with the display device so as to realize unidirectional or bidirectional information transmission;

the monitoring parameter circuit is used for receiving vital sign information of a detected object and transmitting the vital sign information to the control unit of the all-in-one machine;

the integrated machine control unit is also used for receiving and processing the vital sign information and the defibrillation instruction and controlling the integrated machine display unit to display corresponding defibrillation information and monitoring information;

the integrated machine shell is provided with a second accommodating cavity, and the high-voltage capacitor, the charging circuit, the discharging circuit, the integrated machine information transmission unit, the integrated machine control unit and the monitoring parameter circuit are all positioned in the second accommodating cavity;

The defibrillation monitoring integrated machine is provided with a first butt joint structure, wherein the first butt joint structure comprises a detachable bonding structure, a clamping structure and/or a screw fixing structure;

the first storage piece is used for storing accessories for defibrillation and/or monitoring and is detachably connected, non-detachably fixedly connected or integrally formed with the defibrillation monitoring integrated machine.

71. The defibrillation monitoring assembly of claim 70, wherein at least one of the first receiving members is disposed on each of the left and right sides of the defibrillation monitoring unit.

72. The defibrillation monitoring assembly of claim 71, wherein the front side of the first housing member protrudes from the second housing member such that the second housing member and the first housing member form a recessed structure for receiving a display device.

73. The defibrillation monitoring assembly of any one of claims 70-72, wherein the first housing member includes a plurality of separate sub-housing members, the plurality of sub-housing members being removably coupled, non-removably fixedly coupled, or integrally formed therebetween.